System and method for quality assurance of a biosensor test strip

ABSTRACT

The present invention provides a test strip for measuring a signal of interest in a biological fluid when the test strip is mated to an appropriate test meter, wherein the test strip and the test meter include structures to verify the integrity of the test strip traces, to measure the parasitic resistance of the test strip traces, and to provide compensation in the voltage applied to the test strip to account for parasitic resistive losses in the test strip traces.

CLAIM OF PRIORITY

The present application is a continuation application based on and claiming priority to U.S. application Ser. No. 13/748,932, filed Jan. 24, 2013, which is a continuation of and claims priority to U.S. application Ser. No. 13/342,268, filed Jan. 3, 2012, which is a divisional of and claims priority to U.S. application Ser. No. 12/484,603, filed Jun. 15, 2009, which is a Divisional of and claims priority to U.S. application Ser. No. 10/961,352, filed Oct. 8, 2004, which is based on and claims priority to U.S. Application Ser. No. 60/581,002, filed Jun. 18, 2004 which are hereby incorporated by reference in their entirety.

TECHNICAL FIELD OF THE INVENTION

The present invention relates to an apparatus for use in measuring signals such as those related to concentrations of an analyte (such as blood glucose) in a biological fluid as well as those related to interferants (such as hematocrit and temperature in the case of blood glucose) to analyte concentration signals. The invention relates more particularly to a system and method for quality assurance of a biosensor test strip.

BACKGROUND

Measuring the concentration of substances in biological fluids is an important tool for the diagnosis and treatment of many medical conditions. For example, the measurement of glucose in body fluids, such as blood, is crucial to the effective treatment of diabetes.

Diabetic therapy typically involves two types of insulin treatment: basal, and meal-time. Basal insulin refers to continuous, e.g. time-released insulin, often taken before bed. Meal-time insulin treatment provides additional doses of faster acting insulin to regulate fluctuations in blood glucose caused by a variety of factors, including the metabolization of sugars and carbohydrates. Proper regulation of blood glucose fluctuations requires accurate measurement of the concentration of glucose in the blood. Failure to do so can produce extreme complications, including blindness and loss of circulation in the extremities, which can ultimately deprive the diabetic of use of his or her fingers, hands, feet, etc.

Multiple methods are known for determining the concentration of analytes in a blood sample, such as, for example, glucose. Such methods typically fall into one of two categories: optical methods and electrochemical methods. Optical methods generally involve spectroscopy to observe the spectrum shift in the fluid caused by concentration of the analyte, typically in conjunction with a reagent that produces a known color when combined with the analyte. Electrochemical methods generally rely upon the correlation between a current (Amperometry), a potential (Potentiometry) or accumulated charge (Coulometry) and the concentration of the analyte, typically in conjunction with a reagent that produces charge-carriers when combined with the analyte. See, for example, U.S. Pat. No. 4,233,029 to Columbus, U.S. Pat. No. 4,225,410 to Pace, U.S. Pat. No. 4,323,536 to Columbus, U.S. Pat. No. 4,008,448 to Muggli, U.S. Pat. No. 4,654,197 to Lilja et al., U.S. Pat. No. 5,108,564 to Szuminsky et al., U.S. Pat. No. 5,120,420 to Nankai et al., U.S. Pat. No. 5,128,015 to Szuminsky et al., U.S. Pat. No. 5,243,516 to White, U.S. Pat. No. 5,437,999 to Diebold et al., U.S. Pat. No. 5,288,636 to Pollmann et al., U.S. Pat. No. 5,628,890 to Carter et al., U.S. Pat. No. 5,682,884 to Hill et al., U.S. Pat. No. 5,727,548 to Hill et al., U.S. Pat. No. 5,997,817 to Crismore et al., U.S. Pat. No. 6,004,441 to Fujiwara et al., U.S. Pat. No. 4,919,770 to Priedel, et al., and U.S. Pat. No. 6,054,039 to Shieh, which are hereby incorporated in their entireties. The biosensor for conducting the tests is typically a disposable test strip having a reagent thereon that chemically reacts with the analyte of interest in the biological fluid. The test strip is mated to a nondisposable test meter such that the test meter can measure the reaction between the analyte and the reagent in order to determine and display the concentration of the analyte to the user.

FIG. 1 schematically illustrates a typical prior art disposable biosensor test strip, indicated generally at 10 (see, for example, U.S. Pat. Nos. 4,999,582 and 5,438,271, assigned to the same assignee as the present application, and incorporated herein by reference). The test strip 10 is formed on a nonconductive substrate 12, onto which are formed conductive areas 14,16. A chemical reagent 18 is applied over the conductive areas 14,16 at one end of the test strip 10. The reagent 18 will react with the analyte of interest in the biological sample in a way that can be detected when a voltage potential is applied between the measurement electrodes 14 a and 16 a.

The test strip 10 therefore has a reaction zone 20 containing the measurement electrodes 14 a,16 a that comes into direct contact with a sample that contains an analyte for which the concentration in the sample is to be determined. In an amperometric or coulometric electrochemical measurement system, the measurement electrodes 14 a,16 a in the reaction zone 20 are coupled to electronic circuitry (typically in a test meter (not shown) into which the test strip 10 is inserted, as is well known in the art) that supplies an electrical potential to the measurement electrodes and measures the response of the electrochemical sensor to this potential (e.g. current, impedance, charge, etc.). This response is proportional to the analyte concentration.

The test meter contacts the test strip 10 at contact pads 14 b,16 b in a contact zone 22 of the test strip 10. Contact zone 22 is located somewhat remotely from measurement zone 20, usually (but not always) at an opposite end of the test strip 10. Conductive traces 14 c,16 c couple the contact pads 14 b,16 b in the contact zone 22 to the respective measurement electrodes 14 a,16 a in the reaction zone 20.

Especially for biosensors 10 in which the electrodes, traces and contact pads are comprised of electrically conductive thin films (for instance, noble metals, carbon ink, and silver paste, as non-limiting examples), the resistivity of the conductive traces 14 c,16 c that connect the contact zone 22 to the reaction zone 20 can amount to several hundred Ohms or more. This parasitic resistance causes a potential drop along the length of the traces 14 c,16 c, such that the potential presented to the measurement electrodes 14 a,16 a in the reaction zone 20 is considerably less than the potential applied by the test meter to the contact pads 14 b,16 b of the test strip 10 in the contact zone 22. Because the impedance of the reaction taking place within the reaction zone 20 can be within an order of magnitude of the parasitic resistance of the traces 14 c,16 c, the signal being measured can have a significant offset due to the I-R (current×resistance) drop induced by the traces. If this offset varies from test strip to test strip, then noise is added to the measurement result. Furthermore, physical damage to the test strip 10, such as abrasion, cracks, scratches, chemical degradation, etc. can occur during manufacturing, shipping, storage and/or user mishandling. These defects can damage the conductive areas 14,16 to the point that they present an extremely high resistance or even an open circuit. Such increases in the trace resistance can prevent the test meter from performing an accurate test.

Thus, a system and method are needed that will allow for confirmation of the integrity of test strip traces, for measurement of the parasitic resistance of test strip traces, and for controlling the potential level actually applied to the test strip measurement electrodes in the reaction zone. The present invention is directed toward meeting these needs.

SUMMARY

The present invention provides a test strip for measuring a signal of interest in a biological fluid when the test strip is mated to an appropriate test meter, wherein the test strip and the test meter include structures to verify the integrity of the test strip traces, to measure the parasitic resistance of the test strip traces, and to provide compensation in the voltage applied to the test strip to account for parasitic resistive losses in the test strip traces.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be further described, by way of example only, with reference to the accompanying drawings, in which:

FIG. 1 is schematic plan view of a typical prior art test strip for use in measuring the concentration of an analyte of interest in a biological fluid.

FIG. 2 is a schematic plan view of a first embodiment test strip according to the present invention.

FIG. 3 is a schematic diagram of a first embodiment electronic test circuit for use with the first embodiment test strip of FIG. 2.

FIG. 4 is an exploded assembly view of a second typical test strip for use in measuring the concentration of an analyte of interest in a biological fluid.

FIG. 5 illustrates a view of an ablation apparatus suitable for use with the present invention.

FIG. 6 is a view of the laser ablation apparatus of FIG. 5 showing a second mask.

FIG. 7 is a view of an ablation apparatus suitable for use with the present invention.

FIG. 8 is a schematic plan view of a second embodiment test strip according to the present invention.

FIG. 9 is a schematic diagram of a second embodiment electronic test circuit for use with the second embodiment test strip of FIG. 8.

FIG. 10 is a schematic diagram of a third embodiment electronic test circuit for use with the second embodiment test strip of FIG. 8.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE PRESENT INVENTION

For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiment illustrated in the drawings, and specific language will be used to describe that embodiment. It will nevertheless be understood that no limitation of the scope of the invention is intended. Alterations and modifications in the illustrated device, and further applications of the principles of the invention as illustrated therein, as would normally occur to one skilled in the art to which the invention relates are contemplated, are desired to be protected. In particular, although the invention is discussed in terms of a blood glucose meter, it is contemplated that the invention can be used with devices for measuring other analytes and other sample types. Such alternative embodiments require certain adaptations to the embodiments discussed herein that would be obvious to those skilled in the art.

Although the system and method of the present invention may be used with test strips having a wide variety of designs and made with a wide variety of construction techniques and processes, a first embodiment electrochemical test strip of the present invention is illustrated schematically in FIG. 2, and indicated generally at 200. Portions of test strip 200 which are substantially identical to those of test strip 10 are marked with like reference designators. Referring to FIG. 2, the test strip 200 comprises a bottom substrate 12 formed from an opaque piece of 350 μm thick polyester (such as Melinex 329 available from DuPont) coated on its top surface with a 50 nm conductive gold layer (for instance by sputtering or vapor deposition, by way of non-limiting example). Electrodes, connecting traces and contact pads therefor are then patterned in the conductive layer by a laser ablation process. The laser ablation process is performed by means of an excimer laser which passes through a chrome-on-quartz mask. The mask pattern causes parts of the laser field to be reflected while allowing other parts of the field to pass through, creating a pattern on the gold which is evaporated where contacted by the laser light. The laser ablation process is described in greater detail hereinbelow. For example, working 214 a, counter 216 a, and counter sense 224 a electrodes may be formed as shown and coupled to respective measurement contact pads 214 b, 216 b and 224 b by means of respective traces 214 c, 216 c and 224 c. These contact pads 214 b, 216 b and 224 b provide a conductive area upon the test strip 200 to be contacted by a connector contact of the test meter (not shown) once the test strip 200 is inserted into the test meter, as is well known in the art.

FIGS. 2 and 3 illustrate an embodiment of the present invention that improves upon the prior art test strip designs by allowing for compensation of parasitic I-R drop in the counter electrode line of the test strip. It will be appreciated that the test strip 200 of FIG. 2 is substantially identical to the prior art test strip 10 of FIG. 1, except for the addition of the counter sense electrode 224 a, contact pad 224 b, and trace 224 c. Provision of the counter sense line 224 allows the test meter (as described hereinbelow) to compensate for parasitic resistance between the contact pads 216 b,224 b. Note that the embodiment of FIG. 2 when used with the circuit of FIG. 3 only compensates for the I-R drop on the counter electrode side of the test strip 200. Parasitic resistance on the working electrode side of the test strip 200 cannot be detected using this circuitry, although it could be replicated on the working electrode side if desired, as will be apparent to those skilled in the art with reference to the present disclosure. Further methods for compensating for parasitic resistance on both the working and counter sides of the test strip are presented hereinbelow. The counter sense line of FIG. 2 therefore allows the test meter to compensate for any parasitic resistance potential drop in the counter line 216, as explained in greater detail with respect to FIG. 3.

Referring now to FIG. 3, there is shown a schematic electrical circuit diagram of a first embodiment electrode compensation circuit (indicated generally at 300) housed within the test meter. As indicated, the circuit couples to contact pads 214 b, 216 b and 224 b when the test strip 200 is inserted into the test meter. As will be appreciated by those skilled in the art, a voltage potential is applied to the counter electrode contact pad 216 b, which will produce a current between the counter electrode 216 a and the working electrode 214 a that is proportional to the amount of analyte present in the biological sample applied to the reagent 18. The current from working electrode 214 a is transmitted to working electrode contact pad 214 b by means of working electrode trace 214 c and provided to a current-to-voltage amplifier 310. The analog output voltage of amplifier 310 is converted to a digital signal by analog-to-digital converter (A/D) 312. This digital signal is then processed by microprocessor 314 according to a previously stored program in order to determine the concentration of analyte within the biological sample applied to the test strip 200. This concentration is displayed to the user by means of an appropriate output device 316, such as a liquid crystal display (LCD) screen.

Microprocessor 314 also outputs a digital signal indicative of the voltage potential to be applied to the counter electrode contact pad 216 b. This digital signal is converted to an analog voltage signal by digital-to-analog converter (D/A) 318. The analog output of D/A 318 is applied to a first input of an operational amplifier 320. A second input of the operational amplifier 320 is coupled to counter sense electrode contact pad 224 b. The output of operational amplifier 320 is coupled to the counter electrode contact pad 216 b.

Operational amplifier 320 is connected in a voltage follower configuration, in which the amplifier will adjust its output (within its physical limits of operation) until the voltage appearing at its second input is equal to the commanded voltage appearing at its first input. The second input of operational amplifier 320 is a high impedance input, therefore substantially no current flows in counter sense line 224. Since substantially no current flows, any parasitic resistance in counter sense line 224 will not cause a potential drop, and the voltage appearing at the second input of operational amplifier 320 is substantially the same as the voltage at counter sense electrode 224 a, which is in turn substantially the same as the voltage appearing at counter electrode 216 a due to their close physical proximity. Operational amplifier 320 therefore acts to vary the voltage potential applied to the counter electrode contact pad 216 b until the actual voltage potential appearing at the counter electrode 216 a (as fed back over counter sense line 224) is equal to the voltage potential commanded by the microprocessor 314. Operational amplifier 320 therefore automatically compensates for any potential drop caused by the parasitic resistance in the counter electrode trace 216 c, and the potential appearing at the counter electrode 216 a is the desired potential. The calculation of the analyte concentration in the biological sample from the current produced by the working electrode is therefore made more accurate, since the voltage that produced the current is indeed the same voltage commanded by the microprocessor 314. Without the compensation for parasitic resistance voltage drops provided by the circuit 300, the microprocessor 314 would analyze the resulting current under the mistaken presumption that the commanded voltage was actually applied to the counter electrode 216 a.

Many methods are available for preparing test strips having multiple electrodes, such as carbon ink printing, silver paste silk-screening, scribing metalized plastic, electroplating, chemical plating, and photo-chemical etching, by way of non-limiting example. One preferred method of preparing a test strip having additional electrode sense lines as described herein is by the use of laser ablation techniques. Examples of the use of these techniques in preparing electrodes for biosensors are described in U.S. patent application Ser. No. 09/866,030, “Biosensors with Laser Ablation Electrodes with a Continuous Coverlay Channel” filed May 25, 2001, and in U.S. patent application Ser. No. 09/411,940, entitled “Laser Defined Features for Patterned Laminates and Electrode,” filed Oct. 4, 1999, both disclosures incorporated herein by reference. Laser ablation is particularly useful in preparing test strips according to the present invention because it allows conductive areas having extremely small feature sizes to be accurately manufactured in a repeatable manner. Laser ablation provides a means for adding the extra sense lines of the present invention to a test strip without increasing the size of the test strip.

It is desirable in the present invention to provide for the accurate placement of the electrical components relative to one another and to the overall biosensor. In a preferred embodiment, the relative placement of components is achieved, at least in part, by the use of broad field laser ablation that is performed through a mask or other device that has a precise pattern for the electrical components. This allows accurate positioning of adjacent edges, which is further enhanced by the close tolerances for the smoothness of the edges.

FIG. 4 illustrates a simple biosensor 401 useful for illustrating the laser ablation process of the present invention, including a substrate 402 having formed thereon conductive material 403 defining electrode systems comprising a first electrode set 404 and a second electrode set 405, and corresponding traces 406, 407 and contact pads 408, 409, respectively. Note that the biosensor 401 is used herein for purposes of illustrating the laser ablation process, and that it is not shown as incorporating the sense lines of the present invention. The conductive material 403 may contain pure metals or alloys, or other materials, which are metallic conductors. Preferably, the conductive material is absorptive at the wavelength of the laser used to form the electrodes and of a thickness amenable to rapid and precise processing. Non-limiting examples include aluminum, carbon, copper, chromium, gold, indium tin oxide (ITO), palladium, platinum, silver, tin oxide/gold, titanium, mixtures thereof, and alloys or metallic compounds of these elements. Preferably, the conductive material includes noble metals or alloys or their oxides. Most preferably, the conductive material includes gold, palladium, aluminum, titanium, platinum, ITO and chromium. The conductive material ranges in thickness from about 10 nm to 80 nm, more preferably, 30 nm to 70 nm, and most preferably 50 nm. It is appreciated that the thickness of the conductive material depends upon the transmissive property of the material and other factors relating to use of the biosensor.

While not illustrated, it is appreciated that the resulting patterned conductive material can be coated or plated with additional metal layers. For example, the conductive material may be copper, which is then ablated with a laser into an electrode pattern; subsequently, the copper may be plated with a titanium/tungsten layer, and then a gold layer, to form the desired electrodes. Preferably, a single layer of conductive material is used, which lies on the base 402. Although not generally necessary, it is possible to enhance adhesion of the conductive material to the base, as is well known in the art, by using seed or ancillary layers such as chromium nickel or titanium. In preferred embodiments, biosensor 401 has a single layer of gold, palladium, platinum or ITO.

Biosensor 401 is illustratively manufactured using two apparatuses 10, 10′, shown in FIGS. 4,6 and 7, respectively. It is appreciated that unless otherwise described, the apparatuses 410, 410′ operate in a similar manner. Referring first to FIG. 5, biosensor 401 is manufactured by feeding a roll of ribbon 420 having an 80 nm gold laminate, which is about 40 mm in width, into a custom fit broad field laser ablation apparatus 410. The apparatus 410 comprises a laser source 411 producing a beam of laser light 412, a chromium-plated quartz mask 414, and optics 416. It is appreciated that while the illustrated optics 416 is a single lens, optics 416 is preferably a variety of lenses that cooperate to make the light 412 in a pre-determined shape.

A non-limiting example of a suitable ablation apparatus 410 (FIGS. 5-6) is a customized MicrolineLaser 200-4 laser system commercially available from LPKF Laser Electronic GmbH, of Garbsen, Germany, which incorporates an LPX-400, LPX-300 or LPX-200 laser system commercially available from Lambda Physik AG, Göttingen, Germany and a chromium-plated quartz mask commercially available from International Phototool Company, Colorado Springs, Co.

For the MicrolineLaser 200-4 laser system (FIGS. 5-6), the laser source 411 is a LPX-200 KrF-UV-laser. It is appreciated, however, that higher wavelength UV lasers can be used in accordance with this disclosure. The laser source 411 works at 248 nm, with a pulse energy of 600 mJ, and a pulse repeat frequency of 50 Hz. The intensity of the laser beam 412 can be infinitely adjusted between 3% and 92% by a dielectric beam attenuator (not shown). The beam profile is 27×15 mm² (0.62 sq. inch) and the pulse duration 25 ns. The layout on the mask 414 is homogeneously projected by an optical elements beam expander, homogenizer, and field lens (not shown). The performance of the homogenizer has been determined by measuring the energy profile. The imaging optics 416 transfer the structures of the mask 414 onto the ribbon 420. The imaging ratio is 2:1 to allow a large area to be removed on the one hand, but to keep the energy density below the ablation point of the applied chromium mask on the other hand. While an imaging of 2:1 is illustrated, it is appreciated that the any number of alternative ratios are possible in accordance with this disclosure depending upon the desired design requirements. The ribbon 420 moves as shown by arrow 425 to allow a number of layout segments to be ablated in succession.

The positioning of the mask 414, movement of the ribbon 420, and laser energy are computer controlled. As shown in FIG. 5, the laser beam 412 is projected onto the ribbon 420 to be ablated. Light 412 passing through the clear areas or windows 418 of the mask 414 ablates the metal from the ribbon 420. Chromium coated areas 424 of the mask 414 blocks the laser light 412 and prevent ablation in those areas, resulting in a metallized structure on the ribbon 420 surface. Referring now to FIG. 6, a complete structure of electrical components may require additional ablation steps through a second mask 414′. It is appreciated that depending upon the optics and the size of the electrical component to be ablated, that only a single ablation step or greater than two ablation steps may be necessary in accordance with this disclosure. Further, it is appreciated that instead of multiple masks, that multiple fields may be formed on the same mask in accordance with this disclosure.

Specifically, a second non-limiting example of a suitable ablation apparatus 410′ (FIG. 7) is a customized laser system commercially available from LPKF Laser Electronic GmbH, of Garbsen, Germany, which incorporates a Lambda STEEL (Stable energy eximer laser) laser system commercially available from Lambda Physik AG, Göttingen, Germany and a chromium-plated quartz mask commercially available from International Phototool Company, Colorado Springs, Co. The laser system features up to 1000 mJ pulse energy at a wavelength of 308 nm. Further, the laser system has a frequency of 100 Hz. The apparatus 410′ may be formed to produce biosensors with two passes as shown in FIGS. 5 and 6, but preferably its optics permit the formation of a 10×40 mm pattern in a 25 ns single pass.

While not wishing to be bound to a specific theory, it is believed that the laser pulse or beam 412 that passes through the mask 414, 414′, 414″ is absorbed within less than 1 μm of the surface 402 on the ribbon 420. The photons of the beam 412 have an energy sufficient to cause photo-dissociation and the rapid breaking of chemical bonds at the metal/polymer interface. It is believed that this rapid chemical bond breaking causes a sudden pressure increase within the absorption region and forces material (metal film 403) to be ejected from the polymer base surface. Since typical pulse durations are around 20-25 nanoseconds, the interaction with the material occurs very rapidly and thermal damage to edges of the conductive material 403 and surrounding structures is minimized. The resulting edges of the electrical components have high edge quality and accurate placement as contemplated by the present invention.

Fluence energies used to remove or ablate metals from the ribbon 420 are dependent upon the material from which the ribbon 420 is formed, adhesion of the metal film to the base material, the thickness of the metal film, and possibly the process used to place the film on the base material, i.e. supporting and vapor deposition. Fluence levels for gold on KALADEX® range from about 50 to about 90 mJ/cm², on polyimide about 100 to about 120 mJ/cm², and on MELINEX® about 60 to about 120 mJ/cm². It is understood that fluence levels less than or greater than the above mentioned can be appropriate for other base materials in accordance with the disclosure.

Patterning of areas of the ribbon 420 is achieved by using the masks 414, 414′. Each mask 414, 414′ illustratively includes a mask field 422 containing a precise two-dimensional illustration of a pre-determined portion of the electrode component patterns to be formed. FIG. 5 illustrates the mask field 422 including contact pads and a portion of traces. As shown in FIG. 6, the second mask 414′ contains a second corresponding portion of the traces and the electrode patterns containing fingers. As previously described, it is appreciated that depending upon the size of the area to be ablated, the mask 414 can contain a complete illustration of the electrode patterns (FIG. 7), or portions of patterns different from those illustrated in FIGS. 5 and 6 in accordance with this disclosure. Preferably, it is contemplated that in one aspect of the present invention, the entire pattern of the electrical components on the test strip are laser ablated at one time, i.e., the broad field encompasses the entire size of the test strip (FIG. 7). In the alternative, and as illustrated in FIGS. 5 and 6, portions of the entire biosensor are done successively.

While mask 414 will be discussed hereafter, it is appreciated that unless indicated otherwise, the discussion will apply to masks 414′, 414″ as well. Referring to FIG. 5, areas 424 of the mask field 422 protected by the chrome will block the projection of the laser beam 412 to the ribbon 420. Clear areas or windows 418 in the mask field 422 allow the laser beam 412 to pass through the mask 414 and to impact predetermined areas of the ribbon 420. As shown in FIG. 5, the clear area 418 of the mask field 422 corresponds to the areas of the ribbon 420 from which the conductive material 403 is to be removed.

Further, the mask field 422 has a length shown by line 430 and a width as shown by line 432. Given the imaging ratio of 2:1 of the LPX-200, it is appreciated that the length 30 of the mask is two times the length of a length 434 of the resulting pattern and the width 432 of the mask is two times the width of a width 436 of the resulting pattern on ribbon 420. The optics 416 reduces the size of laser beam 412 that strikes the ribbon 420. It is appreciated that the relative dimensions of the mask field 422 and the resulting pattern can vary in accordance with this disclosure. Mask 414′ (FIG. 6) is used to complete the two-dimensional illustration of the electrical components.

Continuing to refer to FIG. 5, in the laser ablation apparatus 410 the excimer laser source 411 emits beam 412, which passes through the chrome-on-quartz mask 414. The mask field 422 causes parts of the laser beam 412 to be reflected while allowing other parts of the beam to pass through, creating a pattern on the gold film where impacted by the laser beam 412. It is appreciated that ribbon 420 can be stationary relative to apparatus 410 or move continuously on a roll through apparatus 410. Accordingly, non-limiting rates of movement of the ribbon 420 can be from about 0 m/min to about 100 m/min, more preferably about 30 m/min to about 60 m/min. It is appreciated that the rate of movement of the ribbon 420 is limited only by the apparatus 410 selected and may well exceed 100 m/min depending upon the pulse duration of the laser source 411 in accordance with the present disclosure.

Once the pattern of the mask 414 is created on the ribbon 420, the ribbon is rewound and fed through the apparatus 410 again, with mask 414′ (FIG. 6). It is appreciated, that alternatively, laser apparatus 410 could be positioned in series in accordance with this disclosure. Thus, by using masks 414, 414′, large areas of the ribbon 420 can be patterned using step-and-repeat processes involving multiple mask fields 422 in the same mask area to enable the economical creation of intricate electrode patterns and other electrical components on a substrate of the base, the precise edges of the electrode components, and the removal of greater amounts of the metallic film from the base material.

The second embodiment of the present invention illustrated in FIGS. 8 and 9 improve upon the prior art by providing for I-R drop compensation of both the working and counter electrode leads on the test strip. Referring now to FIG. 8, there is schematically illustrated a second embodiment test strip configuration of the present invention, indicated generally at 800. The test strip 800 comprises a bottom substrate 12 coated on its top surface with a 50 nm conductive gold layer (for instance by sputtering or vapor deposition, by way of non-limiting example). Electrodes, connecting traces and contact pads therefor are then patterned in the conductive layer by a laser ablation process as described hereinabove. For example, working 814 a, working sense 826 a, counter 216 a, and counter sense 224 a electrodes may be formed as shown and coupled to respective measurement contact pads 814 b, 826 b, 216 b and 224 b by means of respective traces 814 c, 826 c, 216 c and 224 c. These contact pads 814 b, 826 b, 216 b and 224 b provide a conductive area upon the test strip 800 to be contacted by a connector contact of the test meter (not shown) once the test strip 800 is inserted into the test meter.

It will be appreciated that the test strip 800 of FIG. 8 is substantially identical to the first embodiment test strip 200 of FIG. 2, except for the addition of the working sense electrode 826 a, contact pad 826 b, and trace 826 c. Provision of the working sense line 826 allows the test meter to compensate for any I-R drop caused by the contact resistance of the connections to the contact pads 814 b and 216 b, and to compensate for the trace resistance of traces 814 c and 216 c.

Referring now to FIG. 9, there is shown a schematic electrical circuit diagram of a second embodiment electrode compensation circuit (indicated generally at 900) housed within the test meter. As indicated, the circuit couples to contact pads 826 b, 814 b, 216 b and 224 b when the test strip 800 is inserted into the test meter. As will be appreciated by those skilled in the art, a voltage potential is applied to the counter electrode contact pad 216 b, which will produce a current between the counter electrode 216 a and the working electrode 814 a that is proportional to the amount of analyte present in the biological sample applied to the reagent 18. The current from working electrode 814 a is transmitted by working electrode trace 814 c to working electrode contact pad 814 b and provided to current-to-voltage amplifier 310. The analog output voltage of amplifier 310 is converted to a digital signal by A/D 312. This digital signal is then processed by microprocessor 314 according to a previously stored program in order to determine the concentration of the analyte of interest within the biological sample applied to the test strip 800. This concentration is displayed to the user by means of LCD output device 316.

Microprocessor 314 also outputs a digital signal indicative of the voltage potential to be applied to the counter electrode contact pad 216 b. This digital signal is converted to an analog voltage signal by D/A 318. The analog output of D/A 318 is applied to a first input of an operational amplifier 320. A second input of the operational amplifier 320 is coupled to an output of operational amplifier 910. Operational amplifier 910 is connected in a difference amplifier configuration using an instrumentation amplifier. A first input of operational amplifier 910 is coupled to working sense electrode contact pad 826 b, while a second input of operational amplifier 910 is coupled to counter sense electrode contact pad 224 b. The output of operational amplifier 320 is coupled to the counter electrode contact pad 216 b.

Operational amplifier 320 is connected in a voltage follower configuration, in which the amplifier will adjust its output (within its physical limits of operation) until the voltage appearing at its second input is equal to the commanded voltage appearing at its first input. Both inputs of operational amplifier 910 are high impedance inputs, therefore substantially no current flows in counter sense line 224 or working sense line 826. Since substantially no current flows, any parasitic resistance in counter sense line 224 or working sense line 826 will not cause a potential drop, and the voltage appearing across the inputs of operational amplifier 910 is substantially the same as the voltage across the measurement cell (i.e. across counter electrode 216 a and working electrode 814 a). Because operational amplifier 910 is connected in a difference amplifier configuration, its output represents the voltage across the measurement cell.

Operational amplifier 320 will therefore act to vary its output (i.e. the voltage potential applied to the counter electrode contact pad 216 b) until the actual voltage potential appearing across the measurement cell is equal to the voltage potential commanded by the microprocessor 314. Operational amplifier 320 therefore automatically compensates for any potential drop caused by the parasitic resistance in the counter electrode trace 216 c, counter electrode contact 216 b, working electrode trace 814 c, and working electrode contact 814 b, and therefore the potential appearing across the measurement cell is the desired potential. The calculation of the analyte concentration in the biological sample from the current produced by the working electrode is therefore made more accurate.

FIG. 10, in conjunction with FIG. 8, illustrates a third embodiment of the present invention that improves over the prior art by providing I-R drop compensation for both the working and counter electrode lines, as well as providing verification that the resistance of both the working and counter electrode lines is not above a predetermined threshold in order to assure that the test meter is able to compensate for the I-R drops. Referring now to FIG. 10, there is shown a schematic electrical circuit diagram of a third embodiment electrode compensation circuit (indicated generally at 1000) housed within the test meter. The electrode compensation circuit 1000 works with the test strip 800 of FIG. 8. As indicated, the circuit couples to contact pads 826 b, 814 b, 216 b and 224 b when the test strip 800 is inserted into the test meter. As will be appreciated by those skilled in the art, a voltage potential is applied to the counter electrode contact pad 216 b, which will produce a current between the counter electrode 216 a and the working electrode 814 a that is proportional to the amount of analyte present in the biological sample applied to the reagent 18. The current from working electrode 814 a is transmitted to working electrode contact pad 814 b by working electrode trace 814 c and provided to current-to-voltage amplifier 310. The output of current-to-voltage amplifier 310 is applied to the input of instrumentation amplifier 1002 which is configured as a buffer having unity gain when switch 1004 in the closed position. The analog output voltage of amplifier 1002 is converted to a digital signal by A/D 312. This digital signal is then processed by microprocessor 314 according to a previously stored program in order to determine the concentration of analyte within the biological sample applied to the test strip 800. This concentration is displayed to the user by means of LCD output device 316.

Microprocessor 314 also outputs a digital signal indicative of the voltage potential to be applied to the counter electrode contact pad 216 b. This digital signal is converted to an analog voltage signal by D/A 318. The analog output of D/A 318 is applied to the input of an operational amplifier 320 that is configured as a voltage follower when switch 1006 is in the position shown. The output of operational amplifier 320 is coupled to the counter electrode contact pad 216 b, which will allow measurement of a biological fluid sample applied to the reagent 18. Furthermore, with switches 1006, 1008 and 1010 positioned as illustrated in FIG. 10, the circuit is configured as shown in FIG. 9 and may be used to automatically compensate for parasitic and contact resistance as described hereinabove with respect to FIG. 9.

In order to measure the amount of parasitic resistance in the counter electrode line 216, switch 1008 is placed in the position shown in FIG. 10, switch 1006 is placed in the position opposite that shown in FIG. 10, while switch 1010 is closed. The operational amplifier 320 therefore acts as a buffer with unity gain and applies a voltage potential to counter electrode contact pad 216 b through a known resistance R_(nom). This resistance causes a current to flow in the counter electrode line 216 and the counter sense line 224 that is sensed by current-to-voltage amplifier 310, which is now coupled to the current sense line through switch 1010. The output of current-to-voltage amplifier 310 is provided to the microprocessor 314 through A/D 312. Because the value of R_(nom) is known, the microprocessor 314 can calculate the value of any parasitic resistance in the counter sense line 224 and the counter electrode line 216. This parasitic resistance value can be compared to a predetermined threshold stored in the test meter to determine if physical damage has occurred to the test strip 800 or if nonconductive buildup is present on the contact pads to such an extent that the test strip 800 cannot be reliably used to perform a test. In such situations, the test meter may be programmed to inform the user that an alternate test strip should be inserted into the test meter before proceeding with the test.

In order to measure the amount of parasitic resistance in the working electrode line 814, switches 1006 and 1008 are placed in the position opposite that shown in FIG. 10, while switch 1010 is opened. The operational amplifier 320 therefore acts as a buffer with unity gain and applies a voltage potential to working sense contact pad 826 b through a known resistance R_(nom). This resistance causes a current to flow in the working sense line 826 and the working electrode line 814 that is sensed by current-to-voltage amplifier 310. The output of current-to-voltage amplifier 310 is provided to the microprocessor 314 through A/D 312. Because the value of R_(nom) is known, the microprocessor 314 can calculate the value of any parasitic resistance in the working sense line 826 and the working electrode line 814. This parasitic resistance value can be compared to a predetermined threshold stored in the test meter to determine if physical damage has occurred to the test strip 800 or if nonconductive buildup is present on the contact pads to such an extent that the test strip 800 cannot be reliably used to perform a test. In such situations, the test meter may be programmed to inform the user that an alternate test strip should be inserted into the test meter before proceeding with the test.

All publications, prior applications, and other documents cited herein are hereby incorporated by reference in their entirety as if each had been individually incorporated by reference and fully set forth.

While the invention has been illustrated and described in detail in the drawings and foregoing description, the description is to be considered as illustrative and not restrictive in character. Only the preferred embodiment, and certain other embodiments deemed helpful in further explaining how to make or use the preferred embodiment, have been shown. All changes and modifications that come within the spirit of the invention are desired to be protected. 

What is claimed is:
 1. A circuit for a test meter adapted to be operatively coupled to a biosensor strip, the circuit comprising: a difference amplifier having first and second difference amplifier inputs and a difference amplifier output, wherein the first difference amplifier input is operatively coupled to a first connector contact of the test meter and the second difference amplifier input is operatively coupled to a second connector contact of the test meter; a reference voltage source; and a voltage follower amplifier having first and second voltage follower inputs and a voltage follower output, wherein the first voltage follower input is coupled to the reference voltage source, the second voltage follower input is coupled to the difference amplifier output, and the voltage follower output is configured to be operatively coupled to a third connector contact of the test meter; wherein the first, second and third connector contacts are configured to be operatively coupled to respective first, second and third contact pads of a corresponding biosensor strip inserted into the test meter, and wherein the difference amplifier output represents a voltage difference between the first and second connector contacts of the test meter, and wherein the voltage follower amplifier is operatively configured to generate a voltage from the voltage follower output such that the voltage at the second voltage follower input is generally equal to the voltage at the first voltage follower input.
 2. The circuit of claim 1, wherein the reference voltage source comprises a microprocessor operatively coupled to the first voltage follower input, wherein the microprocessor is configured to generate a signal indicative of a desired voltage potential to be applied from the voltage follower output.
 3. The circuit of claim 2, wherein the signal generated by the microprocessor comprises a digital signal, the circuit further comprising a converter having a digital input operatively coupled to the microprocessor and an analog output operatively coupled to the first voltage follower input, the converter configured to receive the digital signal at the digital input, convert the digital signal to an analog signal, and output the analog signal.
 4. The circuit of claim 2, the circuit further comprising a fourth connector contact of the test meter configured to be operatively coupled to a fourth contact pad of a corresponding biosensor strip inserted into the test meter, the fourth connector contact being operatively coupled to the microprocessor.
 5. The circuit of claim 4, wherein the desired voltage potential comprises a voltage potential to be applied across a measurement cell of the biosensor strip, wherein the measurement cell is operatively coupled to the first, second, third and fourth contact pads via separate respective traces, and wherein the separate respective traces are subject to parasitic resistance and wherein the operative couplings of the first, second, third and fourth contact pads of the biosensor strip to the respective first, second, third and fourth connector contacts of the test meter are subject to contact resistance.
 6. The circuit of claim 1, wherein the first and second difference amplifier inputs comprise high impedance inputs wherein substantially no current flows therein.
 7. A method for generating a voltage substantially compensated for voltage potential drops caused by one or more of parasitic resistance in conductive traces of a biosensor test strip and contact resistance in the coupling of biosensor test strip contact pads to connector contacts of a test meter, the method comprising the steps of: operatively coupling a biosensor test strip to a test meter, the biosensor test strip comprising a first measurement electrode and a second measurement electrode, a first conductive trace operatively coupling a first contact pad and the first measurement electrode, a second conductive trace operatively coupling a second contact pad and the first measurement electrode, a third conductive trace operatively coupling a third contact pad and the second measurement electrode, and a fourth conductive trace operatively coupling a fourth contact pad and the second measurement electrode; the test meter having a circuit comprising a difference amplifier having first and second difference amplifier inputs and a difference amplifier output, wherein the first difference amplifier input is operatively coupled to a first connector contact of the test meter and the second difference amplifier input is operatively coupled to a second connector contact of the test meter, the first and second connector contacts of the test meter being operatively coupled respectively to the second and fourth contact pads of the biosensor test strip when the biosensor test strip is operatively coupled to the test meter, the first and second difference amplifier inputs comprising high impedance inputs so that substantially no current flows from the second contact pad to the first connector contact or from the fourth contact pad to the second connector contact, the circuit further comprising a reference voltage source and a voltage follower amplifier having first and second voltage follower inputs and a voltage follower output, wherein the first voltage follower input is coupled to the reference voltage source, the second voltage follower input is coupled to the difference amplifier output, and the voltage follower output is operatively coupled to a third connector contact of the test meter being operatively coupled to the first contact pad of the biosensor test strip when the biosensor test strip is operatively coupled to the test meter; outputting from the reference voltage source a signal indicative of a desired voltage potential to be applied across the first measurement electrode and the second measurement electrode; applying from the voltage follower output a voltage potential to the third connector contact of the test meter and producing a current between the first measurement electrode and the second measurement electrode; by the voltage follower amplifier, adjusting an output from the voltage follower output until a voltage potential at the second voltage follower input is substantially equal to the desired voltage potential; wherein the voltage potential at the second voltage follower input represents the voltage potential across the first and second measurement electrodes, and wherein when the adjusted output from the voltage follower output is such that the voltage potential at the second voltage follower input is substantially equal to the desired voltage potential then the voltage potential across the first and second measurement electrodes is substantially equal to the desired voltage potential and the adjusted output is substantially compensated for voltage drop caused by one or more of parasitic resistance in the first and third conductive traces and contact resistance in the coupling of the biosensor test strip contact pads to the connector contacts of a test meter.
 8. The method of claim 7, further comprising the step of measuring the current produced between the first and second measurement electrodes, said measuring comprising transmitting the current through the third conductive trace to a microprocessor of the test meter and determining a concentration of an analyte the amount of which is proportional to the current produced.
 9. The method of claim 8, wherein the measuring step further comprises providing the current to a current-to-voltage amplifier generating an analog output voltage, providing the analog output voltage to an analog-to-digital converter converting the analog output voltage to a digital signal, and providing the digital signal to the microprocessor.
 10. The method of claim 8, further comprising the step of displaying the concentration to a user by means of an LCD output device operatively coupled to the microprocessor. 